Three-dimensional finite element modeling of the human external ear: Simulation study of the bone conduction occlusion effect

Brummund, Martin; Sgard, Franck; Petit, Yvan; Laville, Frédéric

doi:10.1121/1.4864484

Cited by 33 publications

(63 citation statements)

References 24 publications

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“…A more comprehensive finite element model of the middle ear for BC was presented by Homma et al (2009). The occlusion effect have been investigated by both lumped element models (Schroeter et al, 1986;Stenfelt et al, 2007) and finite element models (Brummund et al, 2014). The most comprehensive work of a finite element model of a whole human head was presented by Taschke et al (2006).…”

Section: Introductionmentioning

confidence: 99%

Inner ear contribution to bone conduction hearing in the human

Stenfelt

2015

Hearing Research

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Bone conduction (BC) hearing relies on sound vibration transmission in the skull bone.Several clinical findings indicate that in the human, the skull vibration of the inner ear dominates the response for BC sound. Two phenomena transform the vibrations of the skull surrounding the inner ear to an excitation of the basilar membrane, (1) inertia of the inner ear fluid and (2) compression and expansion of the inner ear space. The relative importance of these two contributors were investigated using an impedance lumped element model. By dividing the motion of the inner ear boundary in common and differential motion it was found that the common motion dominated at frequencies below 7 kHz but above this frequency differential motion was greatest. When these motions were used to excite the model it was found that for the normal ear, the fluid inertia response was up to 20 dB greater than the compression response. This changed in the pathological ear where, for example, otosclerosis of the stapes depressed the fluid inertia response and improved the compression response so that inner ear compression dominated BC hearing at frequencies above 400 Hz.The model was also able to predict experimental and clinical findings of BC sensitivity in the literature, for example the so called Carhart notch in otosclerosis, increased BC sensitivity in superior semicircular canal dehiscence, and altered BC sensitivity following a vestibular fenestration and RW atresia.

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Section: Introductionmentioning

confidence: 99%

Inner ear contribution to bone conduction hearing in the human

Stenfelt

2015

Hearing Research

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“…One way to circumvent this problem is to use a model that can simulate BC excitation. Several such models have been devised to investigate a specific aspect of BC stimulation, for example the occlusion effect (Brummund et al, 2014;Schroeter et al, 1986;Stenfelt et al, 2007), middle ear inertia (Homma et al, 2009;Williams et al, 1990), and inner ear fluid inertia and compression (Bohnke et al, 2006;Kim et al, 2011;Schick, 1991;Stenfelt, 2015). These models are often specific meaning they only investigate a single or a couple of phenomena and not the complete response of the ear to BC stimulation.…”

Section: Introductionmentioning

confidence: 99%

Model predictions for bone conduction perception in the human

Stenfelt

2016

Hearing Research

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Five different pathways are often suggested as important for bone conducted (BC) sound: (1) sound pressure in the ear canal, (2) inertia of the middle ear ossicles, (3) inertia of the inner ear fluid, (4) compression of the inner ear space, and (5) pressure transmission from the skull interior. The relative importance of these pathways was investigated with an acousticimpedance model of the inner ear. The model incorporated data of BC generated ear canal sound pressure, middle ear ossicle motion, cochlear promontory vibration, and intracranial sound pressure. With BC stimulation at the mastoid, the inner ear inertia dominated the excitation of the cochlea but inner ear compression and middle ear inertia were within 10 dB for almost the entire frequency range of 0.1 to 10 kHz. Ear canal sound pressure gave little contribution at the low and high frequencies, but was around 15 dB below the total contribution at the mid frequencies. Intracranial sound pressure gave responses similar to the others at low frequencies, but decreased with frequency to a level of 55 dB below the total contribution at 10 kHz. When the BC inner ear model was evaluated against AC stimulation at threshold levels, the results were close up to approximately 4 kHz but deviated significantly at higher frequencies. 3 Highlights• A model for BC simulates the contribution from 5 components.• The inner ear compression and inertia and middle ear inertia are most important.• The contribution from intracranial sound pressure is insignificant at higher frequencies.• The model provides similar BM excitation for AC and BC threshold stimulation up to 4 kHz. KeywordsBone conduction, inner ear model, fluid inertia, inner ear compression, middle ear inertia

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“…geometrical variations of the EC have been frequently mentioned as a factor that can affect the sound pressure level (SPL) in both the open EC [25] and the occluded EC [11,31]. The inter-individual variability of the dynamic properties of the EC tissues can also result in SPL variations in the EC [12,8]. Even if these factors are frequently reported in the literature to qualitatively explain the variation of the EP attenuation measurements, their precise impacts on the attenuation have never been investigated and quantified separately.…”

Section: Introductionmentioning

confidence: 99%

“…In Viallet et al [29], the authors accounted for the biological tissues surrounding the ear canal via a mechanical boundary impedance condition but did not take into account the part of the incident acoustic energy which could flow directly through the skin into the unoccluded part of the EC. The geometrical reconstruction of an individual EC including the surrounding tissues is a difficult and highly time consuming process (see [8,22]). In recent works [32], a 2D axisymmetric model of the silicone-lined EC to mimic the effect of the skin was developed to study the effect of the artificial skin present in the available ATF.…”

Section: Introductionmentioning

confidence: 99%